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Data Quality and Data Cleaning: An Overview Tamraparni Dasu Theodore Johnson {tamr,johnsont}@research.att.com AT&T Labs - Research Acknowledgements • We would like to thank the following people who contributed to this tutorial and to our book, Exploratory Data Mining and Data Quality (Wiley) Deepak Agarwal, Dave Belanger, Bob Bell, Simon Byers, Corinna Cortes, Ken Church, Christos Faloutsos, Mary Fernandez, Joel Gottlieb, Andrew Hume, Nick Koudas, Elefteris Koutsofios, Bala Krishnamurthy, Ken Lyons, David Poole, Daryl Pregibon, Matthew Roughan, Gregg Vesonder, and Jon Wright. 2 3 Learning Objectives • Data Quality: The nature of the beast – – – – DQ is pervasive and expensive The problems are messy and unstructured Cannot be pigeonholed into clearly defined problems or disciplines As a consequence, there is very little research and few systematic solutions. • Purpose of the tutorial – Define a framework for the problem of data quality, place the existing work within this structure – Discuss methods for detecting, defining, measuring and resolving data quality issues – Identify challenges and opportunities – Make research directions clear. 4 Overview • Data Quality – Motivation – The meaning of data quality (1) – The data quality continuum – The meaning of data quality (2) – Data quality metrics • Data quality process – Where do problems come from – How can they be resolved • Technical Tools – Process management – Database – Metadata – Statistics • Case Study • Research directions and references 5 Why DQ? • Data quality problems are expensive and pervasive – DQ problems cost hundreds of billions of $$$ each year. • Lost revenues, credibility, customer retention – Resolving data quality problems is often the biggest effort in a data mining study. • 50%-80% of time in data mining projects spent on DQ – Interest in streamlining business operations databases to increase operational efficiency (e.g. cycle times), reduce costs, conform to legal requirements 6 The Meaning of Data Quality (1) 7 Meaning of Data Quality (1) • Data do not conform to expectations, opaque – Data do not match up to specifications • violations of data types, schema • glitches e.g. missing, inconsistent and incomplete data, typos – The specs are inaccessible : complex, lack of metadata, hidden rules, no documentation, word of mouth, changing. • Many sources and manifestations – Manual errors, HW/SW constraints, shortcuts in data processing. 8 Example T.Das |55536o8327 |24.95|Y|- |0.0|1000 Ted J.|555-360-8779|2000 |N|M|NY|1000 • Can we interpret the data? – What do the fields mean? – Units of measurement? Field three is Revenue. In dollars or cents? • Data glitches – Typos, multiple formats, missing / default values • Metadata and domain expertise – Field seven is Usage. Is it censored? • Field 4 is a censored flag. How to handle censored data? 9 10 Missing Data & Defaults 1818|5|NA|NA|NA|NA|NA|NA|NA|NA|0.000000|0.000 000|0.000000|0.000000|NA|NA|NA|NA|NA|NA|NA|N A|NA|NA|NA|NA|0.000000 …… 8560|4448|47041.000000|46969.000000|472.000000 |472.000000|46636.000000|46564.000000|466.0000 00|466.000000 ……. 195|1081|7829073.000000|7814692.000000|25849.0 00000|25849.000000|10418657.000000|10405704.0 00000|27897.000000 …… 11 Common Data Glitches • Systemic changes to data which are external to the recorded process. – Changes in data layout / data types • Integer becomes string, fields swap positions, etc. – Changes in scale / format • Dollars vs. euros – Temporary reversion to defaults • Failure of a processing step – Missing and default values • “0 represents both missing and default values” – Gaps in time series • Especially when records represent incremental changes. 12 Conventional Definition of Data Quality • Accuracy – The data was recorded correctly. • Completeness – All relevant data was recorded. • Uniqueness – Entities are recorded once. • Timeliness – The data is kept up to date. • Consistency – The data agrees with itself. 13 Problems • Not measurable – Accuracy and completeness are difficult, perhaps impossible to measure. • Rigid and static • Context independent – No accounting for what is important. • Aggregates can tolerate inaccuracies but signatures cannot – Incomplete: interpretability, accessibility, metadata, relevance to analysis, etc.? • Vague – The conventional definitions provide no guidance towards practical improvements of the data. 14 Finding a modern definition • We need a definition of data quality which – Reflects the use of the data – Leads to improvements in processes – Is measurable (we can define metrics) • First, we need a better understanding of how and where data quality problems occur – The data quality continuum 15 The Data Quality Continuum • Data/information is not static, it flows in a data collection and usage process – – – – – – Data gathering Data delivery Data storage Data integration Data retrieval Data mining/analysis • Problems can and do arise at all of these stages • End-to-end, continuous monitoring needed 16 Data Gathering • How does the data enter the system? • Sources of problems: – Manual entry – No uniform standards for content and formats – Parallel data entry (duplicates) – Approximations, surrogates – SW/HW constraints – Measurement errors. 17 Solutions • Potential Solutions: – Preemptive: • Process architecture (build in integrity checks) • Process management (reward accurate data entry, data sharing, documentation, data stewards) – Retrospective: • Cleaning focus (duplicate removal, merge/purge, name & address matching, field value standardization) • Diagnostic focus (automated detection of glitches). 18 Data Delivery • Data sent from source to destination – hops • Destroying or mutilating information by inappropriate pre-processing – Inappropriate aggregation – Nulls converted to default values • Loss of data: – Buffer overflows – Transmission problems – No checks • Did all the files arrive in their entirety? 19 Solutions • Build reliable transmission protocols – Use a relay server • Verification – Checksums, verification parser – Do the uploaded files fit an expected pattern? • Relationships – Are there dependencies between data streams and processing steps • Interface agreements – Data quality commitment from the data stream supplier. 20 Data Storage • Problems in physical storage – Can be an issue, but terabytes are cheap. • Problems in logical storage – Poor metadata. • Data feeds are often derived from application programs or legacy data sources. • Inappropriate data models. • Missing timestamps, incorrect normalization, etc. – Ad-hoc modifications. • Structure the data to fit the GUI. – Hardware / software constraints. • Data transmission via Excel spreadsheets, Y2K 21 Solutions • Metadata – Document and publish data specifications in real time. • Planning – Provide for worst case scenarios. – Size the resources to the data feeds. • Data exploration – Use data browsing and data mining tools to examine the data. • Does it meet the specifications? • Has something changed? • Departure from expected values and process? 22 Data Integration • Combine data sets (acquisitions, across departments). • Common source of problems – Heterogeneous data : no common key, different field formats • Approximate matching (e.g., names and addresses) – Different definitions • What is a customer: an account, an individual, a contract … – Time synchronization • Does the data relate to the same time periods? Are the time windows compatible? – Legacy data • IMS, spreadsheets, ad-hoc structures – Sociological factors • Reluctance to share – loss of power. 23 Solutions • Commercial Tools – Significant body of research in data integration – Many tools for address matching, schema mapping are available. • Data browsing and integration – Many hidden problems and meanings : extract metadata. – View before and after results : anomalies in integration? • Manage people and processes – End-to-end accountability: data steward? – Reward data sharing and data maintenance 24 Data Retrieval • Exported data sets are often an extract of the actual data. Problems occur because: – Source data not properly understood. – Need for derived data not understood. – Simple mistakes. • Inner join vs. outer join • Understanding NULL values • Computational constraints – E.g., too expensive to give a full history, instead use a snapshot. • Incompatibility – EBCDIC? 25 Solutions • Tools – use appropriate ETL, EDM and XML tools • Testing – Test queries to make sure that the result matches with what is expected • Plan ahead – Make sure that the retrieved data can be stored, delivered as per specifications 26 Data Mining and Analysis • Data collected for analysis and mining • Problems in the analysis. – Scale and performance – Confidence bounds? – Black boxes and dart boards • “Don’t need no analysts” – Attachment to models – Insufficient domain expertise – Casual empiricism 27 Solutions • Data exploration – Determine which models and techniques are appropriate, find data bugs, develop domain expertise. • Continuous analysis – Are the results stable? How and why do they change? • Accountability – Validate analysis – Make the analysis part of the feedback loop to improve data processes 28 The Meaning of Data Quality (2) 29 Meaning of Data Quality Revisited • Conventional definitions: completeness, uniqueness, consistency, accuracy etc. – measurable? • Modernize definition of DQ in the context of the DQ continuum • Depends on data paradigms (data gathering, storage) – – – – – – – Federated data High dimensional data Descriptive data Longitudinal data Streaming data Web (scraped) data Numeric vs. categorical vs. text data 30 DQ Meaning Revisited • Depends on applications (delivery, integration, analysis) – Business operations – Aggregate analysis, prediction – Customer relations … • Data Interpretation – Know all the rules used to generate the data • Data Suitability – Use of proxy data – Relevant data is missing Increased DQ Increased reliability and usability (directionally correct) 31 Data Quality Metrics 32 Data Quality Constraints • Many data quality problems can be captured by static constraints based on the schema. – Nulls not allowed, field domains, foreign key constraints, etc. • Many others are due to problems in workflow, and can be captured by dynamic constraints – E.g., orders above $200 are processed by Biller 2 • The constraints follow an 80-20 rule – A few constraints capture most cases, thousands of constraints to capture the last few cases. • Constraints are measurable. Data Quality Metrics? 33 Data Quality Metrics • Need to quantify data quality – – – – DQ is complex, no set of numbers will be perfect Context and domain dependent Should indicate what is wrong and how to improve Should be measurable, practical and implementable • Types of metrics – Static vs. dynamic constraints – Operational vs. diagnostic • Metrics should be directionally correct with an improvement in use of the data. • A very large number of metrics are possible – Choose the most important ones depending on context. 34 Examples of Data Quality Metrics • Usability and reliability of the data – Conformance to schema (static) • Evaluate constraints on a snapshot. – Conformance to business rules (dynamic) • Evaluate constraints on changes in the database • Across time or across databases. – Accuracy • Perform inventory (expensive), or use proxy (track complaints). – – – – Accessibility, Interpretability Glitches in analysis Successful completion of end-to-end process Increase in automation, others … 35 Technical Tools 36 Technical Approaches • Need a multi-disciplinary approach – No single approach solves all problems • Process management – Pertains to data process and flows – Checks and controls, audits • Database – Storage, access, manipulation and retrieval • Metadata / domain expertise – Interpretation and understanding • Statistics – Analysis, diagnosis, model fitting, prediction, decision making … 37 Process Management • Business processes which encourage DQ – Assign dollars to quality problems – Standardize content and formats – Enter data once, enter it correctly (incentives for sales, customer care) – Automation – Assign responsibility: data stewards – Continuous end-to-end data audits and reviews • Transitions between organizations. – Data Monitoring – Data Publishing – Feedback loops 38 Data Monitoring • Data processing systems are often thought of as open-loop systems. – Process and forget … – Computers don’t make mistakes, do they? • Analogy to control systems : feedback loops. – Monitor the system to detect difference between actual and intended – Feedback loop to correct the behavior of earlier components 39 Example • Sales, provisioning, and billing for telecommunications service – Many stages involving handoffs between organizations and databases – Simplified picture • Transition between organizational boundaries is a common cause of problems. • Natural feedback loops – Customer complains if the bill is too high • Missing feedback loops – No complaints if we undercharge. 40 Example Sales Order Customer Customer Care Billing Customer Account Information Provisioning Existing Data Flow Missing Data Flow 41 Data Monitoring • Use data monitoring to add missing feedback loops. • Methods: – Data tracking / auditing • Follow a sample of transactions through the workflow. – Reconciliation of incrementally updated databases with original sources. – Mandated consistency with a Database of Record (DBOR). – Data Publishing 42 Data Publishing • Make the contents of a database available in a readily accessible and digestible way – Web interface (universal client). – Data Squashing : Publish aggregates, cubes, samples, parametric representations. – Publish the metadata. • Close feedback loops – Many people look at data, use different sections for different purposes in different ways, “test” the data • Surprisingly difficult sometimes. – Organizational boundaries, loss of control interpreted as loss of power, desire to hide problems. 43 Databases Technology • Why use databases? – Statisticians spend a lot of time on EDA, sanity checks and summarization. – Powerful data analysis and query tools. – Extensive data import/export/access facilities. – Data validation. – Integration of data from multiple sources. • Most data lives in databases 44 Relational Databases • A database is a collection of tables. • Each table is a collection of records. • Each record contains values of named fields. – The values can be NULL, – Meaning either “don’t know” or “not applicable”. • A key is a field (or set of fields) whose value is unique in every record of a table – Identifies the thing described by the record • Data from different tables is associated by matching on field values (join). • Foreign key join: all values of one field are contained in the set of values of another field, which is a key. 45 SalesForce Name Joe Ted Mary Sunita ID 1101 1113 1211 1514 BaseSalary 10,000 20,000 15,000 8,000 Commission 14% 10% 12% 15% Orders ID 22122 22124 22325 23001 SalesForceID 1101 1514 1211 1514 SaleDate 8/3/2002 8/8/2002 8/15/2002 8/24/2002 Foreign Key DeliveryDate 8/9/2002 8/23/2002 NULL 9/4/2002 46 SQL (Structured Query Language) How many sales are pending delivery, by salesperson? Specify attributes Select S.Name, count(*) From SalesForce S, Orders O Where S.ID = O.SalesForceID And O.DeliveryDate IS NULL Group By S.Name Specify data sources Integrate DeliveryDate is NULL means that it is pending Count by salesperson name 47 Database Tools • Most DBMS’s provide many data consistency tools – Data types • String, date, float, integer – Domains (restricted set of field values) • Restriction on field values e.g. telephone number – Constraints • Column Constraints – Not Null, Unique, Restriction of values • Table constraints – Primary and foreign key constraints – Powerful query language – Triggers – Timestamps, temporal DBMS 48 Then why is every DB dirty? • Consistency constraints are often not used – Cost of enforcing the constraint • E.g., foreign key constraints, triggers. – Loss of flexibility – Constraints not understood • E.g., large, complex databases with rapidly changing requirements – DBA does not know / does not care. • Complex, heterogeneous, poorly understood data – Merged, federated, web-scraped DBs. • Undetectable problems – Incorrect values, missing data • Metadata not maintained • Database is too complex to understand 49 Semantic Complexity • Different ideas about exactly what the data represents leads to errors. • Example: – HR uses the SalesForce table to record the current status of the sales staff. When a person leaves employment, their record is deleted. – The CFO uses the SalesForce and Orders tables to compute the volume of sales each quarter. • Strangely, their numbers are always too low … – Enforcing foreign key join by deletion will drop records from Orders table which is even worse. – CFO needs historical view of Salesforce table to get accurate answers • DQ problems arise when information is not fully 50 communicated to the users Tools • • • • Extraction, Transformation, Loading Approximate joins Duplicate finding Database exploration 51 Data Loading • The data might be derived from a questionable source. – Federated database, Merged databases – Text files, log records – Web scraping • The source database might admit a limited set of queries – E.g., query a web page by filling in a few fields. • The data might need restructuring – Field value transformation – Transform tables (e.g. denormalize, pivot, fold) 52 ETL • Provides tools to – – – – – Access data (DB drivers, web page fetch, parse tools) Validate data (ensure constraints) Transform data (e.g. addresses, phone numbers) Transform tables (pivot, etc.) Load data • Design automation – Schema mapping – Queries to data sets with limited query interfaces (web queries) 53 (example of pivot) unpivot Customer Bob Bob Bob Sue Sue Pete Pete Part bolt nail rivet glue nail bolt glue pivot Sales 32 112 44 12 8 421 6 Customer Bob Sue Pete bolt nail rivet glue 32 112 44 0 0 8 0 12 421 0 0 6 54 (Example of schema mapping [MHH00]) Address ID Addr Mapping 1 Professor ID Name Sal Personnel Name Sal Student Name GPA Yr PayRate Rank HrRate Mapping 2 WorksOn Name Proj Hrs ProjRank 55 Web Scraping • Lots of data in the web, but embedded in unwanted data – E.g., track sales rank on Amazon • Problems: – Limited query interfaces • Fill in forms – “Free text” fields • E.g. addresses – Inconsistent output • I.e., html tags which mark interesting fields might be different on different pages. – Rapid change without notice. 56 Tools • Automated generation of web scrapers – Excel will load html tables • Automatic translation of queries – Given a description of allowable queries on a particular source • Monitor results to detect quality deterioration • Extraction of data from free-form text – E.g. addresses, names, phone numbers – Auto-detect field domain 57 Approximate Matching • Relate tuples whose fields are “close” – Approximate string matching • Generally, based on edit distance. • Fast SQL expression using a q-gram index – Approximate tree matching • For XML • Much more expensive than string matching • Recent research in fast approximations – Feature vector matching • Similarity search • Many techniques discussed in the data mining literature. – Ad-hoc matching • Look for a clever trick. 58 Approximate Joins and Duplicate Elimination • Perform joins based on incomplete or corrupted information. – Approximate join : between two different tables – Duplicate elimination : within the same table • More general than approximate matching. – Correlating information : verification from other sources, e.g. usage correlates with billing. – Missing data : Need to use several orthogonal search and scoring criteria. 59 Potentially Incorrectly Merged Records Usage B (111-BAD-DATA) A (111-BAD-DATA) Time 60 (Approximate Join Example) Sales “Gen” bucket Sales Genrl. Eclectic General Magic Gensys Genomic Research Provisioning Provisioning Genrl. Electric Genomic Research Gensys Inc. Match Genrl. Eclectic Genomic Research Gensys Genrl. Electric Genomic Research Gensys Inc. 61 Database Exploration • Tools for finding problems in a database – Similar to data quality mining • Simple queries are effective: Select Field, count(*) from Table Group by Field Order by Cnt Desc – Hidden NULL values at the head of the list, typos at the end of the list • Look at a sample of the data in the table. 62 Database Profiling • Systematically collect summaries of the data in the database – – – – Number of rows in each table - completeness Number of unique, null values of each field - missing Skewness of distribution of field values - outliers Data type, length of the field – constraint satisfaction • Use free-text field extraction to guess field types (address, name, zip code, etc.) – Functional dependencies, keys – Join paths • Does the database contain what we think it contains? – Usually not. 63 Finding Join Paths • Correlate information. • In large databases, hundreds of tables, thousands of fields. • Our experience: field names are very unreliable. • Use data types and field characterization to narrow the search space. • More sophisticated techniques – min hash sampling 64 Finding Keys and Functional Dependencies • Key: set of fields whose value is unique in every row • Functional Dependency: A set of fields which determine the value of another field – E.g., ZipCode determines the value of State • Problems: keys not identified, uniqueness not enforced, hidden keys and functional dependencies. • Key finding is expensive: O(fk) Count Distinct queries to find all keys of up to k fields. • Fortunately, we can prune the search space if we search only for minimal keys and FDs • Approximate keys : almost but not quite unique. • Approximate FD : similar idea 65 Domain Expertise • Data quality gurus: “We found these peculiar records in your database after running sophisticated algorithms!” Domain Experts: “Oh, those apples - we put them in the same baskets as oranges because there are too few apples to bother. Not a big deal. We knew that already.” 66 Why Domain Expertise? • DE is important for understanding the data, the problem and interpreting the results • “The counter resets to 0 if the number of calls exceeds N”. • “The missing values are represented by 0, but the default billed amount is 0 too.” • Insufficient DE is a primary cause of poor DQ – data are unusable • DE should be documented as metadata 67 Where is the Domain Expertise? • Usually in people’s heads – seldom documented • Fragmented across organizations • Lost during personnel and project transitions • If undocumented, deteriorates and becomes fuzzy over time 68 Metadata • Data about the data • Data types, domains, and constraints help, but are often not enough • Interpretation of values – Scale, units of measurement, meaning of labels • Interpretation of tables – Frequency of refresh, associations, view definitions • Most work done for scientific databases – Metadata can include programs for interpreting the data set. 69 XML • Data interchange format, based on SGML • Tree structured – Multiple field values, complex structure, etc. • “Self-describing” : schema is part of the record – Field attributes • DTD : minimal schema in an XML record. <tutorial> <title> Data Quality and Data Cleaning: An Overview <\title> <Conference area=“database”> JSM <\Conference> <author> T. Dasu <bio> Statistician <\bio> <\author> <author> T. Johnson <institution> AT&T Labs <\institution> <\author> <\tutorial> 70 What’s Missing? • Most metadata relates to static properties – Database schema – Field interpretation • Data use and interpretation requires dynamic properties as well – Business process rules? – 80-20 rule 71 Lineage Tracing • Record the processing used to create data – Coarse grained: record processing of a table – Fine grained: record processing of a record • Record graph of data transformation steps. • Used for analysis, debugging, feedback loops 72 Statistical approaches • No explicit DQ methods – Traditional statistical data collected from carefully designed experiments, often tied to analysis • Four broad categories can be adapted for DQ – Missing, incomplete, ambiguous or damaged data e.g truncated, censored – Suspicious or abnormal data e.g. outliers – Testing for departure from models – Goodness-of-fit 73 Missing Data • Missing data - values, attributes, entire records, entire sections • Missing values and defaults are indistinguishable • Truncation/censoring - not aware, mechanisms not known • Problem: Misleading results, bias. 74 Detecting Missing Data • Overtly missing data – Match data specifications against data - are all the attributes present? – Scan individual records - are there gaps? – Rough checks : number of files, file sizes, number of records, number of duplicates – Compare estimates (averages, frequencies, medians) with “expected” values and bounds; check at various levels of granularity since aggregates can be misleading. 75 Missing data detection (cont.) • Hidden damage to data – Values are truncated or censored - check for spikes and dips in distributions and histograms – Missing values and defaults are indistinguishable - too many missing values? metadata or domain expertise can help – Errors of omission e.g. all calls from a particular area are missing - check if data are missing randomly or are localized in some way 76 Imputing Values to Missing Data • In federated data, between 30%-70% of the data points will have at least one missing attribute • If we ignore all records with a missing value – Data wastage – Remaining data is seriously biased – Lack of confidence in results • Understanding pattern of missing data unearths data integrity issues 77 Missing Value Imputation - 1 • Standalone imputation – Mean, median, other point estimates – Assume: Distribution of the non-missing values – Does not take into account inter-relationships – Introduces bias – Convenient, easy to implement 78 Missing Value Imputation - 2 • Better imputation - use attribute relationships • Assume : all prior attributes are populated X1| X2| X3| X4| X5 1.0| 20| 3.5| 4| . 1.1| 18| 4.0| 2| . 1.9| 22| 2.2| .| . 0.9| 15| .| .| . • Two techniques – Regression (parametric), – Propensity score (nonparametric) 79 Missing Value Imputation –3 • Regression method – Use linear regression, sweep left-to-right X3=a+b*X2+c*X1; X4=d+e*X3+f*X2+g*X1, and so on – X3 in the second equation is estimated from the first equation if it is missing 80 Missing Value Imputation - 3 • Propensity Scores (nonparametric) – Let Yj=1 if Xj is missing, 0 otherwise – Estimate P(Yj =1) based on X1 through X(j-1) using logistic regression – Group by propensity score P(Yj =1) – Within each group, estimate missing Xjs from known Xjs using approximate Bayesian bootstrap. – Repeat until all attributes are populated. 81 Missing Value Imputation - 4 • Arbitrary missing pattern – Markov Chain Monte Carlo (MCMC) – Assume multivariate Normal, with Q – (1) Simulate missing X, given Q estimated from observed X ; (2) Re-compute Q using filled in X – Repeat until stable. – Expensive: Used most often to induce monotonicity • Note that imputed values are useful in aggregates but can not be trusted individually 82 Censoring and Truncation • Well studied in Biostatistics, relevant to duration data • Censored - Measurement is bounded but not precise e.g. Call duration > 20 are recorded as 20 • Truncated - Data point dropped if it exceeds or falls below a certain bound e.g. customers with less than 2 minutes of calling per month 83 Censored time intervals 84 Censoring/Truncation (cont.) • If censoring/truncation mechanism not known, analysis can be inaccurate and biased • Metadata should record the existence as well as the nature of censoring/truncation 85 Spikes usually indicate censored time intervals caused by resetting of timestamps to defaults 86 Suspicious Data • Consider the data points 3, 4, 7, 4, 8, 3, 9, 5, 7, 6, 92 • “92” is suspicious - an outlier • Outliers are potentially legitimate • Often, they are data or model glitches • Or, they could be a data miner’s dream, e.g. highly profitable customers 87 Courtesy R. K. Pearson: See references. 88 Courtesy R. K. Pearson: See references. 89 Outliers • Outlier – “departure from the expected” • Types of outliers – defining “expected” • Many approaches – Error bounds, tolerance limits – control charts – Model based – regression depth, analysis of residuals – Geometric – Distributional – Time Series outliers 90 Control Charts • Quality control of production lots • Typically univariate: X-Bar, R, CUSUM • Distributional assumptions for charts not based on means e.g. R–charts • Main steps (based on statistical inference) – Define “expected” and “departure” e.g. Mean and standard error based on sampling distribution of sample mean (aggregate); – Compute aggregate each sample – Plot aggregates vs. expected and error bounds – “Out of Control” if aggregates fall outside bounds 91 An Example (http://www.itl.nist.gov/div898/handbook/mpc/section3/mpc3521.htm) 92 Multivariate Control Charts - 1 • Bivariate charts: – based on bivariate Normal assumptions – component-wise limits lead to Type I, II errors • Depth based control charts (nonparametric): – map n-dimensional data to one dimension using depth e.g. Mahalanobis – Build control charts for depth – Compare against benchmark using depth e.g. Q-Q plots of depth of each data set 93 Bivariate Control Chart Y X 94 Multivariate Control Charts - 2 • Multiscale process control with wavelets: – Detects abnormalities at multiple scales as large wavelet coefficients. – Useful for data with heteroscedasticity – Applied in chemical process control 95 Model Fitting and Outliers • Models summarize general trends in data – more complex than simple aggregates – e.g. linear regression, logistic regression focus on attribute relationships • Goodness of fit tests (DQ for analysis/mining) – check suitableness of model to data – verify validity of assumptions – data rich enough to answer analysis/business question? • Data points that do not conform to well fitting models are potential outliers 96 Set Comparison and Outlier Detection • “Model” consists of partition based summaries • Perform nonparametric statistical tests for a rapid section-wise comparison of two or more massive data sets • If there exists a baseline “good’’ data set, this technique can detect potentially corrupt sections in the test data set 97 Goodness of Fit - 1 • Chi-square test – attribute independence – Observed (discrete) distribution= Assumed distribution? • • • • Tests for Normality Q-Q plots (visual) Kolmogorov-Smirnov test Kullback-Liebler divergence 98 Goodness of Fit - 2 • Analysis of residuals – Departure of individual points from model – Patterns in residuals reveal inadequacies of model or violations of assumptions – Reveals bias (data are non-linear) and peculiarities in data (variance of one attribute is a function of other attributes) – Residual plots 99 Detecting heteroscedasticity 4 3 2 1 0 -1 -2 -3 -2.0 -1.5 -1.0 -.5 0.0 .5 1.0 1.5 2.0 Regression Standardized Predicted Value http://www.socstats.soton.ac.uk/courses/st207307/lecture_slides/l4.doc 100 Goodness of Fit -3 • Regression depth – measures the “outlyingness” of a model, not an individual data point – indicates how well a regression plane represents the data – If a regression plane needs to pass through many points to rotate to the vertical (non-fit) position, it has high regression depth 101 Geometric Outliers • Define outliers as those points at the periphery of the data set. • Peeling : define layers of increasing depth, outer layers contain the outlying points – Convex Hull: peel off successive convex hull points. – Depth Contours: layers are the data depth layers. • Efficient algorithms for 2-D, 3-D. • Computational complexity increases rapidly with dimension. – Ω(Nceil(d/2)) complexity for N points, d dimensions 102 Distributional Outliers • For each point, compute the maximum distance to its k nearest neighbors. – DB(p,D)-outlier : at least fraction p of the points in the database lie at distance greater than D. • Fast algorithms – One is O(dN2), one is O(cd+N) • Local Outliers : adjust definition of outlier based on density of nearest data clusters. • Note – performance guarantees but no accuracy guarantees 103 Time Series Outliers • Data is a time series of measurements of a large collection of entities (e.g. customer usage). • Vector of measurements define a trajectory for an entity. • A trajectory can be glitched, or it can make radical but valid changes. • Approach: develop models based on entity’s past behavior (within) and all entity behavior (relative). • Find potential glitches: – Common glitch trajectories – Deviations from within and relative behavior. 104 105 A Case Study in Data Cleaning DQ in Business Operations Data Quality Process Data Gathering Data Loading (ETL) Data Scrub – data profiling, validate data constraints Data Integration – functional dependencies Develop Biz Rules and Metrics – interact with domain experts Stabilize Biz Rules Data Quality Check Validate biz rules Verify Biz Rules Recommendations Quantify Results Summarize Learning 107 Case Study • Provisioning inventory database – Identify equipment needed to fulfill sales order. • False positives : provisioning delay • False negatives : decline the order, purchase unnecessary equipment • The initiative – Validate the corporate inventory – Build a database of record. – Has top management support. 108 Task Description • OPED : operations database – Machine components available in each local warehouse • IOWA : information warehouse – Machine descriptions: components – Owner descriptions:name, business, address • SAPDB : Sales and provisioning database – Inventory DB used by sales force when selling • Audit data flow OPED IOWA SAPDB 109 Data Audit –1 • Data gathering: – Manual extraction of data from IOWA and SAPDB • Format changes at every run, difficult to automate audits – Documented metadata was insufficient • OPED - warehouseid (a primary match key) is corrupted, undocumented workaround process used • 70 machine types in OPED, only 10 defined and expected • Unclear biz rules for flows between OPED and IOWA, and IOWA and SAPDB – “Satellite” databases at local sites not integrated with main databases – Informal and unstandardized means of data exchange e.g., excel spreadsheets, e-mail text messages, faxes, paper and pencil 110 Data Audit - 2 • Data and process flows: – SAPDB contains only 15% of the records in OPED or IOWA • Business rules that govern data flows unclear – Numerous workaround processes • Override prohibited machine types through manual intervention • Push through incomplete information using dummies “123123-1234” • Manual “correction” of keys- “But we cleaned the data!” • Permitting multiple entry of same information by multiple sources – duplicate records with minor variations 111 Data Audit - 3 • Data interpretation – No consensus among experts on definitions and use of machines and components • Many conference calls with top management support – Timing issues • Downstream systems unaware of delays in upstream systems e.g., sections of data are not updated but no one is aware 112 Data Improvements - 1 • Satellite databases integrated into main databases (completeness). • Address mismatches cleaned up (accuracy). – And so was the process which caused the mismatches • Metadata - defined and documented business definitions and rules that govern data flows (interpretability, accessibility) – E.g. only certain machine types should flow to SAPDB • Removed duplicates (uniqueness) 113 Data Improvements - 2 • Automated data gathering and eliminated manual workarounds (increase in automation) • Increased usable inventory by ensuring compliance to business rules (usability) • Successful end-to-end completion went up from 50% to 98% (conformance to business rules) • Automated auditing process (reliability) – Regular checks and cleanups 114 DQ Metrics Used • Proportion of data that flows through correctly • Extent of automation • Access and interpretability – Documentation – Metadata • Others … 115 Accomplishments • DBoR! Repaired ~ 70% of the data • Authoritative documentation of metadata and domain expertise • Inventory up by 15% (tens of thousands of records, millions of $$) • Automated, end-to-end and continuous auditing system in place • In 100 days! 116 What did we learn? • Take nothing for granted – Metadata is frequently wrong – Data transfers never work the first time – Manual entry and intervention causes problems; Automate processes – Remove the need for manual intervention; Make the regular process reflect practice. • Defining data quality metrics is key – Defines and measures the problem. – Creates metadata. • Organization-wide data quality – Need to show $$ impact and get blessings of top brass – Data steward for the end-to-end process. – Data publishing to establish feedback loops. 117 Commercial DQ Tools 118 SAS Data Quality - Cleanse • The SAS Data Quality Solution bundles the following tools: – SAS/Warehouse Administrator software: structures operational data. See www.sas.com/rnd/warehousing/wa. – SAS Data Quality — Cleanse software: prevent defective data, reduce redundancies, and standardize data elements. See www.sas.com/rnd/warehousing/cleanse. – dfPower Studio from DataFlux: normalize inconsistent data, improve the merging capability of data from dissimilar sources, and identify critical data quality issues. http://support.sas.com/rnd/warehousing/quality/index.html 119 IBM DataJoiner • DB2 DataJoiner is the multidatabase server solution for accessing heterogeneous data — IBM or other relational or non-relational, local or remote — as if it were in a single data store. http://www-3.ibm.com/software/data/datajoiner/features.html 120 Research Directions 121 Challenges in Data Quality • Multifaceted nature – Problems are introduced at all stages of the process. • but especially at organization boundaries. – Many types of data and applications. • Highly complex and context-dependent – The processes and entities are complex. – Many problems in many forms. • No silver bullet – Need an array of tools. – And the discipline to use them. 122 Data Quality Research • Burning issues – Data quality mining – Advanced browsing / exploratory data mining – Reducing complexity – Data quality metrics 123 Data Quality Mining • Systematically searching data for inconsistencies, flaws and glitches • Opportunities – nonparametric goodness-of-fit techniques – model based outlier detection, confidence limits – finding “holes” in data – anomaly analysis for new types of data • streaming, text, image 124 Data Quality Metrics • Measuring data quality - scoring? – Need a flexible, composite score; weights? • Constraint framework – constraint satisfaction, proportions and confidence limits • Resampling methods – Statistical distances, sampling distributions and confidence bounds 125 Interesting Data Quality Research • Recent research that is interesting and important for an aspect of data quality. • CAVEAT – This list is meant to be an example – It is not exhaustive. – It contains a sampling of recent research – Subjective (my perspective) 126 Bellman • T. Dasu, T. Johnson, S. Muthukrishnan, V. Shkapenyuk, Mining database structure; or, how to build a data quality browser, SIGMOD 2002 pg 240-251 • “Data quality” browser – Summarizes, identifies anomalies – Finds potential ways of matching up hundreds of data sets containing thousands of attributes • Perform profiling on the database – Counts, keys, join paths, substring associations • Use to explore large databases. – Extract missing metadata. 127 Model Checking • Freeny, A. E. & Nair, V. N. (1994). Methods for assessing distributional assumptions in one and two sample problems, in J. Stanford & S. Vardeman (eds), Probabilistic and Statistical Methods in the Physical Sciences, Academic Press, New York, chapter 7. • Empirical methods for assessing goodness-of-fit – graphical methods, formal goodness-of-fit methods – complete as well as censored data 128 Bayesian Model Averaging • Hoeting, J., Madigan D., Raftery, A. and Volinsky, C. (1999) Bayesian Model Averaging, Statistical Science 14, 382-401. • Averaging over models to account for uncertainty in models – need to choose class of models – need to choose priors for competing models – computational difficulties 129 Signatures • • C. Cortes and D. Pregibon, “Signaturebased methods for data streams”, Data Mining and Knowledge Discovery, July 2001. For characterizing data streams – Signatures capture typical behavior – Updated over time – Outliers with respect to the signature could potentially represent fraud 130 Contaminated Data • Pearson, R. K. “Outliers in process modeling and identification”, IEEE Transactions on Control Systems Technology, Volume: 10 Issue: 1 , Jan 2002, Page(s): 55 -63 • Methods – identifying outliers (Hampel limits), – missing value imputation, – compare results of fixed analysis on similar data subsets – others 131 Data Depth • Multivariate ordering – Convex hull peeling, half plane, simplicial – Potential for nonparametric partitioning and data exploration – Identifying differences in sets and isolating outliers – Difficult to implement in higher dimensions • Work by Huber, Oja, Tukey, Liu & Singh, Rousseeuw et al,Ng et al, others … 132 Depth Contours • S. Krishnan, N. Mustafa, S. Venkatasubramanian, Hardware-Assisted Computation of Depth Contours. SODA 2002 558-567. • Parallel computation of depth contours using graphics card hardware. – Cheap parallel processor – Depth contours : • Multidimensional analog of the median • Used for nonparametric statistics 133 Points Depth Contours 134 Data Quality Mining : Deviants • H.V. Jagadish, N. Koudas, S. Muthukrishnan, Mining Deviants in a Time Series Database, VLDB 1999 102-112. • Deviants : points in a time series which, when removed, yield best accuracy improvement in a histogram. • Use deviants to find glitches in time series data. 135 Potters Wheel • V. Raman, J.M. Hellerstein, Potter's Wheel: An Interactive Data Cleaning System, VLDB 2001 pg. 381-390 • ETL tool, especially for web scraped data. • Two interesting features: – Scalable spreadsheet : interactive view of the results of applying a data transformation. – Field domain determination • Apply domain patterns to fields, see which ones fit best. • Report exceptions. 136 Conclusions • Now that processing is cheap and access is easy, the big problem is data quality. • Where are the statisticians? – Statistical metrics for data quality – Rank based methods, nonparametric methods that scale – Provide confidence guarantees • Considerable research (mostly from process management, CS, DB), but highly fragmented • Lots of opportunities for applied research. 137 Bibliography 138 References • Process Management – http://web.mit.edu/tdqm/www/about.html • Missing Value Imputation – Schafer, J. L. (1997), Analysis of Incomplete Multivariate Data, New York: Chapman and Hall – Little, R. J. A. and D. B. Rubin. 1987. "Statistical Analysis with Missing Data." New York: John Wiley & Sons. – Release 8.2 of SAS/STAT - PROCs MI, MIANALYZE – “Learning from incomplete data”. Z. Ghahramani and M. I. Jordan. AI Memo 1509, CBCL Paper 108, January 1995, 11 pages. 139 References • Censoring / Truncation – Survival Analysis: Techniques for Censored and Truncated Data”. John P. Klein and Melvin L. Moeschberger – "Empirical Processes With Applications to Statistics”. Galen R. Shorack and Jon A. Wellner; Wiley, New York; 1986. • Control Charts – A.J. Duncan, Quality Control and Industrial Statistics. Richard D. Irwin, Inc., Ill, 1974. – Liu, R. Y. and Singh, K. (1993). A quality index based on data depth and multivariate rank tests. J. Amer. Statist. Assoc. 88 252-260. 13 – Aradhye, H. B., B. R. Bakshi, R. A. Strauss,and J. F. Davis (2001). Multiscale Statistical Process Control Using Wavelets Theoretical Analysis and Properties. Technical Report, Ohio State University 140 References • Set comparison – Theodore Johnson, Tamraparni Dasu: Comparing Massive HighDimensional Data Sets. KDD 1998: 229-233 – Venkatesh Ganti, Johannes Gehrke, Raghu Ramakrishnan: A Framework for Measuring Changes in Data Characteristics. PODS 1999, 126-137 • Goodness of fit – Computing location depth and regression depth in higher dimensions. Statistics and Computing 8:193-203. Rousseeuw P.J. and Struyf A. 1998. – Belsley, D.A., Kuh, E., and Welsch, R.E. (1980), Regression Diagnostics, New York: John Wiley and Sons, Inc. 141 References • Geometric Outliers – Computational Geometry: An Introduction”, Preparata, Shamos, Springer-Verlag 1988 – “Fast Computation of 2-Dimensional Depth Contours”, T. Johnson, I. Kwok, R. Ng, Proc. Conf. Knowledge Discovery and Data Mining pg 224-228 1988 • Distributional Outliers – “Algorithms for Mining Distance-Based Outliers in Large Datasets”, E.M. Knorr, R. Ng, Proc. VLDB Conf. 1998 – “LOF: Identifying Density-Based Local Outliers”, M.M. Breunig, H.-P. Kriegel, R. Ng, J. Sander, Proc. SIGMOD Conf. 2000 • Time Series Outliers – “Hunting data glitches in massive time series data”, T. Dasu, T. Johnson, MIT Workshop on Information Quality 2000. 142 References • ETL – “Data Cleaning: Problems and Current Approaches”, E. Rahm, H.H. Do, Data Engineering Bulletin 23(4) 3-13, 2000 – “Declarative Data Cleaning: Language, Model, and Algorithms”, H. Galhardas, D. Florescu, D. Shasha, E. Simon, C.-A. Saita, Proc. VLDB Conf. 2001 – “Schema Mapping as Query Discovery”, R.J. Miller, L.M. Haas, M.A. Hernandez, Proc. 26th VLDB Conf. Pg 77-88 2000 – “Answering Queries Using Views: A Survey”, A. Halevy, VLDB Journal, 2001 – “A Foundation for Multi-dimensional Databases”, M. Gyssens, L.V.S. Lakshmanan, VLDB 1997 pg. 106-115 – “SchemaSQL – An Extension to SQL for Multidatabase Interoperability”, L.V.S. Lakshmanan, F. Sadri, S.N. Subramanian, ACM Transactions on Database Systems 26(4) 476-519 2001 – “Don't Scrap It, Wrap It! A Wrapper Architecture for Legacy Data Sources”, M.T. Roth, P.M. Schwarz, Proc. VLDB Conf. 266-275 1997 – “Declarative Data Cleaning: Language, Model, and Algorithms – ”, H. Galhardas, D. Florescu, D. Shasha, E. Simon, C. Saita, Proc. VLDB Conf. Pg 371-380 2001 143 References • Web Scraping – “Automatically Extracting Structure from Free Text Addresses”, V.R. Borkar, K. Deshmukh, S. Sarawagi, Data Engineering Bulletin 23(4) 27-32, 2000 – “Potters Wheel: An Interactive Data Cleaning System”, V. Raman and J.M. Hellerstein, Proc. VLDB 2001 – “Accurately and Reliably Extracting Data From the Web”, C.A. Knoblock, K. Lerman, S. Minton, I. Muslea, Data Engineering Bulletin 23(4) 33-41, 2000 • Approximate String Matching – “A Guided Tour to Approximate String Matching”, G. Navarro, ACM Computer Surveys 33(1):31-88, 2001 – “Using q-grams in a DBMS for Approximate String Processing”, L. Gravano, P.G. Ipeirotis, H.V. Jagadish, N. Koudas, S. Muthukrishnan, L. Pietarinen, D. Srivastava, Data Engineering Bulletin 24(4):28-37,2001. 144 References • Other Approximate Matching – “Approximate XML Joins”, N. Koudas, D. Srivastava, H.V. Jagadish, S. Guha, T. Yu, SIGMOD 2002 – “Searching Multimedia Databases by Content”, C. Faloutsos, Klewer, 1996. • Approximate Joins and Duplicate Detection – “The Merge/Purge Problem for Large Databases”, M. Hernandez, S. Stolfo, Proc. SIGMOD Conf pg 127-135 1995 – “Real-World Data is Dirty: Data Cleansing and the Merge/Purge Problem”, M. Hernandez, S. Stolfo, Data Mining and Knowledge Discovery 2(1)9-37, 1998 – “Telcordia’s Database Reconciliation and Data Quality Analysis Tool”, F. Caruso, M. Cochinwala, U. Ganapathy, G. Lalk, P. Missier, Proc. VLDB Conf. Pg 615-618 2000 – “Hardening Soft Information Sources”, W.W. Cohen, H. Kautz, D. McAllester, Proc. KDD Conf., 255-259 2000 145 References • Data Profiling – “Data Profiling and Mapping, The Essential First Step in Data Migration and Integration Projects”, Evoke Software, http://www.evokesoftware.com/pdf/wtpprDPM.pdf – “TANE: An Efficient Algorithm for Discovering Functional and Approximate Dependencies”, Y. Huhtala, J. K., P. Porkka, H. Toivonen, The Computer Journal 42(2): 100-111 (1999) – “Mining Database Structure; Or, How to Build a Data Quality Browser”, T.Dasu, T. Johnson, S. Muthukrishnan, V. Shkapenyuk, Proc. SIGMOD Conf. 2002 – “Data-Driven Understanding and Refinement of Schema Mappings”, L.-L. Yan, R. Miller, L.M. Haas, R. Fagin, Proc. SIGMOD Conf. 2001 146 References • Metadata – “A Metadata Resource to Promote Data Integration”, L. Seligman, A. Rosenthal, IEEE Metadata Workshop, 1996 – “Using Semantic Values to Facilitate Interoperability Among Heterogenous Information Sources”, E. Sciore, M. Siegel, A. Rosenthal, ACM Trans. On Database Systems 19(2) 255-190 1994 – “XML Data: From Research to Standards”, D. Florescu, J. Simeon, VLDB 2000 Tutorial, http://www-db.research.belllabs.com/user/simeon/vldb2000.ppt – “XML’s Impact on Databases and Data Sharing”, A. Rosenthal, IEEE Computer 59-67 2000 – “Lineage Tracing for General Data Warehouse Transformations”, Y. Cui, J. Widom, Proc. VLDB Conf. 471-480 2001 147 Thank you! Please contact me if you have any questions: [email protected] 148 Additional Algorithms 149 Algorithm (Approximate Matches & Joins, Duplicate Elimination) • Partition data set – By hash on computed key – By sort order on computed key – By similarity search / approximate match on computed key • Perform scoring within the partition – Hash : all pairs – Sort order, similarity search : target record to retrieved records • Record pairs with high scores are matches • Use multiple computed keys / hash functions • Duplicate elimination : duplicate records form an equivalence class. 150 Effective Algorithm Data Profiling, Finding Keys • Eliminate “bad” fields – Float data type, mostly NULL, etc. • Collect an in-memory sample – Perhaps storing a hash of the field value • Compute count distinct on the sample – High count : verify by count distinct on database table. • Use Tane style level-wise pruning • Stop after examining 3-way or 4-way keys – False keys with enough attributes. 151 Min Hash Sampling Finding Join Paths • Special type of sampling which can estimate the resemblance of two sets – Size of intersection / size of union • Apply to set of values in a field, store the min hash sample in a database – Use an SQL query to find all fields with high resemblance to a given field – Small sample sizes suffice. • Problem: fields which join after a small data transformation – E.g “SS123-45-6789” vs. “123-45-6789” • Solution: collect min hash samples on the qgrams of a field – Alternative: collect sketches of qgram frequency vectors 152 Additional Research References 153 DBXplorer • S. Agrawal, S. Chaudhuri, G. Das, DBXplorer: A System for Keyword-Based Search over Relational Databases, ICDE 2002. • Keyword search in a relational database, independent of the schema. • Pre-processing to build inverted list indices (profiling). • Build join queries for multiple keyword search. 154 Exploratory Data Mining • R.T. Ng, L.V.S. Lakshmanan, J. Han, A. Pang, Exploratory Mining and Pruning Optimizations of Constrained Association Rules, SIGMOD 1998 pg 13-24 • Interactive exploration of data mining (association rule) results through constraint specification. 155 Exploratory Schema Mapping • M.A. Hernandez, R.J. Miller, L.M. Haas, Clio: A Semi-Automatic Tool for Schema Mapping, SIGMOD 2001 • Automatic generation and ranking of schema mapping queries • Tool for suggesting field mappings • Interactive display of alternate query results. 156 Data Quality Mining • F. Korn, S. Muthukrishnan, Y. Zhu, Monitoring Data Quality Problems in Network Databases, submitted for publication • Define probably approximately correct constraints for a data feed (network performance data) – Range, smoothness, balance, functional dependence, unique keys • Automation of constraint selection and threshold setting • Raise alarm when constraints fail. 157 Exploratory Data Mining • J.D. Becher, P. Berkhin, E. Freeman, Automating Exploratory Data Analysis for Efficient Data Mining, KDD 2000 • Use data mining and analysis tools to determine appropriate data models. • In this paper, attribute selection for classification. 158 159 160 OLAP Exploration • S. Sarawagi, G. Sathe, i3: Intelligent, Interactive Investigation of OLAP data cubes, SIGMOD 2000 pg. 589 • Suite of tools (operators) to automate the browsing of a data cube. – Find “interesting” regions 161 Approximate Matching • L. Gravano, P.G. Ipeirotis, N. Koudas, D. Srivastava, Text Joins in a RDBMS for Web Data Integration, WWW2003 • Approximate string matching using IR techniques – Weight edit distance by inverse frequency of differing tokens • If “Corp.” appears often, its presence or absence carries little weight • Define an SQL-queryable index 162